Monitoring and control module for fluid catalytic cracking unit

ABSTRACT

A fluid catalytic cracking (FCC) unit for the production of hydrocarbon products includes a fluid injection system coupled to a reactor by a standpipe. The fluid injection system includes a plurality of nozzles for injecting oil feedstock into the standpipe to react with a catalyst flowing therethrough.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of and priority to U.S. ProvisionalPatent Application Ser. No. 62/058,903, filed Oct. 2, 2014, which isincorporated herein by this reference in its entirety.

BACKGROUND

The present disclosure relates to an apparatus for use in continuouscyclical processes employing fluidized solid techniques, such as ahydrocarbon fluid catalytic cracking (FCC) process, and is particularlydirected to an injector module for introducing feedstocks into a reactorvessel for carrying out FCC processes.

Fluid catalytic cracking (FCC) processes are used in the refining ofpetroleum for producing various products such as low boiling pointhydrocarbon products, especially gasoline, from relatively higherboiling feeds, or feedstocks. There are two pathways for the feed tocrack into gaseous hydrocarbons, i.e., catalytic and thermal. Thermalcracking in a FCC reactor is generally undesirable as this type ofcracking can result in the generation of light gases such as methane inaddition to coke.

Various approaches have been adapted to rapidly break up the fluidfeedstock vaporization. One approach involves the spraying of feedstockoil against a bolt head under pressure to fracture the feedstock. Steamis then used to carry the fractured particles out through a nozzle intothe catalyst flow of the riser section of the FCC reactor. With thisapproach hydrocarbon feedstock is directed in a substantiallyperpendicular direction to the flowing stream of catalyst particles andonto a central strike surface on a target cylinder for disbursing themixture of hydrocarbons and catalyst particles within the FCC reactor.Another approach uses steam flowing into a chamber with the feedstockoil, with the two flows of particles mixing and then flowing through anorifice, or a restricting nozzle, to atomize the mixed fluid. A thirdapproach uses a twisting or spiral shaped nozzle to fracture thefeedstock oil, with steam then added to carry the feedstock oil into thepath of the catalyst.

In all of these installations, the feed injection nozzles and theirmounting arrangements have various known issues. For example, the feedinjection nozzles are subject to erosion and are easily and quicklydegraded by the chemically-active catalysts. The nozzle arrangements aresometimes installed at different levels within the riser, with typically4 to 12 nozzles at each level. Each nozzle projects onto the riser pipewall and through the refractory lining on the inside of the riser pipe,with each of the nozzles having piping attached thereto for the deliveryof feedstock and steam, and sometimes this piping includes drains or“rod out” ports. This nozzle and piping arrangement is very complex,requiring isolation valves and support piping, is very large in size,and is expensive.

If a first nozzle fails in a typical arrangement, a second oppositelypositioned nozzle sprays high velocity fuel with catalyst onto theopposite side of the riser where the first failed nozzle is located,causing erosive or corrosive problems with the refractory lining and/orwall of the riser. This can cause catastrophic failure of the FCCprocess and dangerous operating conditions for plant personnel.Excessive heating of a nozzle assembly located on the riser is adangerous condition for plant personnel who can be easily injured ifrequired to operate a valve or perform other operational or maintenancefunctions on or near the riser. Nozzles can be very expensive, as is thecost to install a replacement nozzle in a riser. One of the reasons forthis high cost is that the piping attached to each nozzle must match inposition and orientation and must be properly positioned for connectionto a nozzle in a very restrictive space involving complex piping.Typically there are 4 or 6 nozzles incorporated, and as you get biggerunits, sometimes there is 8 or 10 nozzles, but in general there are nomore than 10. There appears to be only one assembly in the world thathas up to 14 nozzles in it.

Thus, there is a need for a FCC processing module that is durable andeasily maintainable.

SUMMARY

The present disclosure provides a method and system for the injection ofoil feedstock into a fluid catalytic cracking (FCC) unit used to producevarious hydrocarbon products from the oil feedstock. The atomization, orbreakdown, of the feedstock fluid into a small particle size is requiredin these processes, and the efficiency of the process is related to howwell the feedstock oils are broken down and mixed with other materialsto produce a valuable product.

According to the present disclosure, a fluid injection system includesan injector module coupled to a standpipe of a FCC unit and a datacollection and control module (DCCM) which controls the injection of oilfeedstock into the standpipe through the injector module. The injectormodule has a plurality of nozzles and valves to control a flow ofworking fluid through the nozzles. The nozzles are positioned to injectthe working fluid into a standpipe where the oil feedstock reacts with acatalyst to break down the oil feedstock into various byproducts,including valuable hydrocarbon products.

In illustrative embodiments, the injector module includes a single body,or block, and a plurality of nozzles coupled to the block to extend intothe standpipe. The block is formed to include an internal network ofconduits for flowing the oil feedstock and other processing fluidsthrough the nozzles.

In illustrative embodiments, the DCCM monitors and controls the flow,temperature, pressure, and particle size of the various fluidstravelling through the block for distribution to each nozzle. The DCCMcontrols the injector module to provide accurate, independent operationof each nozzle.

In illustrative embodiments, the fluid injection system is configured tomaximize the operating lifetime of the injector module through safe andefficient removal and replacement of feedstock nozzles, as well as formonitoring of nozzle wear and corrosion during operation to determinewhen a nozzle should be replaced before failure of the nozzle. The fluidinjection system is also configured to maximize the reliability andoperating lifetime of each nozzle by limiting exposure of the nozzle tothe FCC reaction zone, thus minimizing the corrosion and erosionexposure levels while also reducing the nozzle's operating temperatureand size.

In illustrative embodiments, the injector module includes a plurality ofdouble block and bleed valves. The valves block a flow of fluid in twodifferent seating positions, and provide a bleed port between the twoseats, in a single unit. This minimizes the amount of space needed forthe isolation of working fluid from the standpipe in a safe manner tomeet refinery standards. The double block and bleed valves provide forthe safe and effective shutting down of the injector module orindividual nozzle, and the bleeding off of any residual pressure, forthe purpose of performing maintenance, e.g., replacing a nozzle.

In illustrative embodiments, the fluid injection system maximizes yieldsfrom the FCC process by providing for the cool and stable operatingtemperatures for a high temperature hydrocarbon FCC process, which alsoincreases safety for operators of the system. The fluid injection systemalso maximizes the number of feed nozzles for control over oil feedstockdistribution and input, further increasing yields. Various feedstocknozzle configurations can be used to meet an FCC unit's configuration,including the use of multiple injector modules at multiple levels on thestandpipe controlled by a single DCCM.

Additional features of the present disclosure will become apparent tothose skilled in the art upon consideration of illustrative embodimentsexemplifying the best mode of carrying out the disclosure as presentlyperceived.

BRIEF DESCRIPTION OF THE DRAWINGS

The detailed description particularly refers to the accompanying figuresin which:

FIG. 1 is a diagrammatic view of a fluid catalytic cracking unitincorporating an injector module and a data collection and controlmodule in accordance with the present disclosure;

FIG. 2 is a diagrammatic view of a fluid injection system;

FIG. 3 is an upper perspective view of one embodiment of an injectormodule;

FIG. 4 is a side elevation view of the injector module of FIG. 3;

FIG. 5 is a sectional view taken along line 5-5 in FIG. 3;

FIG. 6 is an upper perspective view of a body block of the injectormodule of FIG. 3;

FIG. 7 is a longitudinal sectional view of one embodiment of anoil/steam nozzle used in the injector module;

FIG. 7A is a longitudinal sectional view of another embodiment of anoil/steam nozzle used in the injector module;

FIG. 8 is a longitudinal sectional view of a nozzle-removal tool for usein installing or replacing a nozzle in injector module;

FIG. 9 is a perspective view of a dual block and bleed valve for use incontrolling the oil and steam flow within the injector module;

FIGS. 10 is a longitudinal sectional views of the dual block and bleedvalve of FIG. 9;

FIG. 11 is a view similar to FIG. 10;

FIGS. 12A-12D illustrate a schematic view diagram of various controlsand monitors of the data collection and control module monitoring andcontrolling the operation of the injector module;

FIG. 13 is an upper perspective view of another embodiment of aninjector module;

FIG. 14 is a side elevation view of the injector module of FIG. 13;

FIG. 15 is a sectional view taken along line 15-15 in FIG. 14;

FIG. 16 is a sectional view taken along line 16-16 in FIG. 14;

FIG. 17 is a sectional view taken along line 17-17 in FIG. 14;

FIG. 18 is a sectional view taken along line 18-18 in FIG. 14; and

FIG. 19 is a sectional view taken along line 19-19 in FIG. 14.

DETAILED DESCRIPTION

An illustrative embodiment of a fluid catalytic cracking (FCC) unit 100incorporating a fluid injection system 10 in accordance with the presentdisclosure is shown in FIG. 1. Fluid injection system 10 includes aninjector module 12 and a data collection/control module (DCCM) 14configured to monitor and control injector module 12. FCC unit 100includes a reactor 102 and a standpipe 101 (sometimes referred to as avertical riser section) coupled between reactor 102 and injector module12.

In the illustrative embodiment, fluid injection system 10 is configuredto provide feedstock oil, and other working fluids, into standpipe 101where the feedstock oil reacts with catalyst particles flowing throughstandpipe 101 to break down the feedstock oil into various byproducts assuggested in FIG. 1. The catalyst particles and reacting feedstock oilis transferred into reactor 102 where some of the byproducts of thereaction process (sometimes called a cracking process) are gathered andsent through an outlet gas conduit 103 for further processing andrefinement.

For example, in some embodiments, the reaction process produceshydrocarbon products. In some embodiments the reaction process produceslow boiling point hydrocarbons, such as gasoline, gas oils, and/orgaseous hydrocarbons produced from higher boiling point hydrocarbons. Inone illustrative embodiment, during the cracking process, relativelyhigh boiling oil is converted to lighter oil and forms heating oils andgasoline, or even lighter hydrocarbons. The oil or hydrocarbon feedstockis contacted in one or more reaction zones within reactor 102 with thecatalyst particles and is maintained in a fluidized state underconditions suitable for the above-described conversion of thehydrocarbons. In some embodiments, the catalyst particles are chemicallyactive metallic particles formed to include a large surface area.

In the illustrative embodiment, injector module 12 is configured toprovide a working fluid of feedstock oil and steam into standpipe 101 assuggested in FIG. 1. In some embodiments, residual oil products(sometimes called resid oil), which includes the remains of priordistillation processes of fuel oils and lighter hydrocarbons, is alsooptionally introduced as part of the working fluid. The steam operatesto atomize the oil feed stock and optional resid oils at hightemperatures and pressures to form the working fluid. This working fluidis directed into the standpipe 101 by injector module 12.

DCCM 14 monitors the cracking process and controls injector module 12 tooptimize the composition and flow characteristics of the working fluidto maximize yields of the valuable reaction byproducts as suggested inFIG. 1. The working fluid and catalyst particles move through variousreaction zones within reactor 102 producing the reaction byproducts. Insome embodiments, oil deposited on the catalyst particles is leastpartially removed from by combustion in an oxygen-containing medium. Insome embodiments, reaction byproducts pass through outlet gas conduit103 to a fractionator (not shown), wherein hydrocarbon effluent isseparated into components such as light gases and gasoline, light cycleoil, heavy cycle oil and slurry oil. Various contents of reactor 102 mayalso be recycled along with the feedstock oil to the injector module 12.These contents may include light gases and gasoline which are furtherseparated and processed downstream of reactor 102.

The spent catalyst particles are separated from the reaction byproductsin reactor 102 and sent through a spent-catalyst pipe 105 into aregenerator 104 as suggested in FIG. 1. Regenerator 104 processes thespent catalyst particles to remove unwanted reaction byproducts so thecatalyst particles can be reused in subsequent reactions. Theregenerated catalyst particles are sent through a regenerated-catalystpipe 106 to a connector section 107 coupled to injector module 12. Inthe illustrative embodiment, a lower portion of connector section 107 iscoupled with a pressure source 108 configured to pressurize FCC unit 100to move the catalyst particles toward reactor 102. In the illustrativeembodiment, regenerator 104 is selectively separated from reactor 102and connector section 107 by valves 11, 13 to control the flow ofcatalyst particles through FCC unit 100 as suggested in FIG. 1. Valves11, 13 are electronically actuable through valve controllers 15, 17,respectively, which are controlled by DCCM 14.

In the illustrative embodiment, catalyst regenerator 104 includes arecirculation pipe 25 which controls the rate at which the catalyst isrecirculated within catalyst regenerator 104 during regeneration of thespent catalyst as suggested in FIG. 1. Recirculation of the catalystwithin the catalyst regenerator 104 is regulated by a catalystrecirculation valve 26 controlled by a recirculation catalyst controller28 in connection with DCCM 14. A pressure control valve 21 and adifferential pressure control valve 22 are connected to an upper portionof regenerator 104 by a pressure control pipe 23. Pressure control valve21 and differential pressure control valve 22 regulate the pressurewithin the regenerator 104 and the differential pressure betweenregenerator 104 and the pressure within recirculation pipe 25,respectively. Pressure control valve 21 and differential pressurecontrol valve 22 are coupled to and controlled by pressure controller 44in connection with DCCM 14. Each of the aforementioned controllers 15,17, 24, 28 is coupled to and receives control inputs from DCCM 14 asdescribed in greater detail below.

Injector module 12 includes a manifold 32 and a plurality of nozzles 34as suggested in FIG. 2. A portion of manifold 32 is cut away to viewnozzles 34. Manifold 32 is configured to receive inputs of feedstock oil35, steam 31, and resid oil 33 and mix inputs 31, 33, 35 into a workingfluid for distribution to nozzles 34. The working fluid passes throughnozzles 34 into standpipe 101 to react with the catalyst particles andmove toward reactor 102. Manifold 32 is connected with DCCM 14 toregulate the mixing and distribution of the working fluid to nozzles 34as detailed further below.

In the illustrative embodiment, a condensate collector 36 is connectedwith manifold 32 to receive steam that condenses before distribution tonozzles 34 as suggested in FIG. 2. The heat produced through forming theworking fluid is regulated by a water cooling system 39 connected tomanifold 32 and controlled by DCCM 14. Manifold 32 includes a pluralityof valves, as further discussed below, for regulating the distributionof inputs 31, 33, 35 through injector module 12. In some embodiments,the valves are operated hydraulically through a hydraulic fluiddistribution system 37 controlled by DCCM 14.

Manifold 32 of injector module 12 is attached to and disposed aboutstandpipe 101 as suggested in FIGS. 3-5. Manifold 32 includes a unitarybody block 46 and a flow control assembly 48. Body block 46 is formed toinclude a plurality of internal passageways for distribution of fluidsthrough manifold 32 as suggested in FIG. 6 and further detailed below.Flow control assembly 48 is operated by DCCM 14 and includes a pluralityof multiflow oil control blocks 78 a-78 h and multiflow steam controlblocks 80 a-80 h coupled to body block 46 to control the flow of fluidsthrough body block 46 as suggested in FIG. 3. In the illustrativeembodiment, diversion flow blocks 60, 95, 86, 94 are coupled to bodyblock 46 and configured to receive fluid inputs of steam, feedstock oil,and resid oil for distribution through body block 46 as needed.Operation of diversion flow blocks 60, 95, 86, 94 is controlled by DCCM14.

Body block 46 includes a central tube 52 and a flow network 54 formed inbody block 46 and in fluid communication with central tube 52 assuggested in FIG. 6. Flow network 54 includes a series of cross drilledbores extending into body block 46 from an outer surface such thatopenings into the bores are exposed. Flow network 54 is internal to bodyblock 46, but is shown in solid line for clarity. Control blocks 78 a-78h and 80 a-80 h, and diversion flow blocks 60, 95, 86, 94, are coupledto body block 46 to cover the exposed openings of the bores to controlthe direction of fluids flowing through flow network 54. The crossdrilled bores define separate and distinct fluid passageways inside bodyblock 46 to allow the various input fluids to flow separately from oneanother until they pass through control blocks 78 a-78 h and 80 a-80 hto reach mixing zones to form the working fluid for injection throughnozzles 34 into standpipe 101 as suggested in FIGS. 3-6. As such,individualized external piping for each nozzle 34 is not required,allowing a footprint of injector module 12 to be minimized whileminimizing the spacing between adjacent nozzles 34 so that more nozzles34 can be included within standpipe 101.

A plurality of apertures 41 are formed through an inner surface 42 ofcentral tube 52 and circumferentially spaced apart from one another toreceive nozzles 34 as suggested in FIGS. 5 and 6. Central tube 52 iscoupled to standpipe 101 such that apertures 41 formed through centraltube 52 align with apertures 49 formed through standpipe 101, as well asthrough a refractory liner 47, to allow nozzles 34 to pass intostandpipe 101 as suggested in FIG. 5. Flow network 54 is arranged topass fluid inputs supplied to body block 46 to nozzles 34 as controlledby flow control assembly 48. Refractory liner 47 is abrasion resistantand heat insulating to protect injector module 12 from the reactionprocess.

Various control mechanisms are included in injector module 12 to controlthe flow of working fluid into standpipe 101. In the illustrativeembodiment, first and second diversion flow blocks 60 and 95 are coupledto opposing portions of body block 46 as suggested in FIG. 3. Each ofthe first and second diversion flow blocks 60, 95 is similarlyconfigured and each operates in substantially the same manner. As such,only first diversion flow block 60 will be discussed in detail.

First diversion flow block 60 includes upper and lower diversion flowhousings 60 a and 60 b as suggested in FIGS. 3 and 4. Upper diversionflow housing 60 a is adapted for diverting oil flow within firstdiversion flow block 60, while lower diversion flow housing 60 b isadapted for diverting steam flow within first diversion flow block 60.Upper diversion flow housing 60 a includes an oil inlet 27, with aflange for connecting oil inlet piping, and an oil outlet 29, also witha flange for connecting oil outlet piping. Similarly, lower diversionflow housing 60 b includes a steam inlet 93, with a flange forconnecting steam inlet piping, and a steam outlet 97, also with a flangefor connecting steam outlet piping.

Upper diversion flow housing 60 a further includes an oil diversionvalve 56 having a cylinder 56 a and a cylinder standoff 56 b as shown inFIGS. 4 and 5. When oil diversion valve 56 is closed, oil flows from oilinlet 27 to oil outlet 29 and is diverted away from and bypassesstandpipe 101. In some embodiments, this bypassed oil is sent to afractionator for further processing as suggested by arrow 99 in FIGS. 1and 2. When oil diversion valve 56 is open, oil flows from oil inlet 27into body block 46 as further detailed below.

Lower diversion flow housing 60 b further includes a steam diversionvalve 70 incorporating a cylinder 70 a and a cylinder standoff 70 b asshown in FIGS. 4 and 5. When steam diversion valve 70 is closed, steamflows from steam inlet 93 to steam outlet 97, bypassing standpipe 101.When steam diversion valve 70 is open, steam flows from steam inlet 93into body block 46. The oil and steam diversion valves 56, 70 arecontrolled hydraulically by DCCM 14 as described in detail below. Duringnormal operation, the first and second diversion flow blocks 60, 95allow oil and steam to flow into body block 46, and prevent this flowonly in emergencies or to conduct a nozzle replacement operation asfurther detailed below.

In the illustrative embodiments, flow control assembly 48 includes eightmultiflow oil control blocks 78 a-78 h coupled to an upper portion ofbody block 46 and circumferentially spaced from one another as suggestedin FIG. 3. While eight oil control blocks are shown, more or less blocksmay be used depending on the size of the standpipe and number of nozzlesbeing used. Each multiflow oil control block 78 a-78 h controls the flowof oil, which may be feedstock or resid oil, through flow network 54within body block 46. In some embodiments, multiflow oil control blocks78 a-78 h are each separated into multiple oil control blocks, with eachsubdivided oil control block associated with a single nozzle 34.

Each multiflow oil control block 78 a-78 h includes three upper dualblock and bleed valves 82 a, 82 b and 82 c as illustrated by multiflowoil control block 78 h in FIG. 4. Similarly, each multiflow oil controlblock 78 a-78 h includes three intermediate throttling valves 77 a, 77 band 77 c and three lower dual block and bleed valves 75 a, 75 b and 75c. The three sets of valves are used to direct the flow of oil to threecorresponding nozzles 34. While three sets of valves are shown, more orless sets of valves may be used depending on the number of nozzles beingfed by a particular oil control block.

In the illustrative embodiments, flow control assembly 48 also includeseight multiflow steam control blocks 80 a-80 h coupled to a perimeterportion of body block 46 and circumferentially spaced from one anotheras suggested in FIG. 3. While eight steam control blocks are shown, moreor less blocks may be used depending on the size of the standpipe andnumber of nozzles being used. Each multiflow steam control block 80 a-80h is disposed below a corresponding one of multiflow oil control blocks78 a-78 h. For example, multiflow steam control block 80 h is disposedbelow multiflow oil control block 78 h as suggested in FIG. 4.

Each multiflow steam control block 80 a-80 h includes three upper dualblock and bleed valves 81 a, 81 b and 81 c as illustrated by multiflowsteam control block 80 h in FIG. 4. Similarly, each multiflow steamcontrol block 80 a-80 h includes three intermediate throttling valves 83a, 83 b and 83 c and three lower dual block and bleed valves 85 a, 85 band 85 c. The three sets of valves are used to direct the flow of steamto three corresponding nozzles 34. While three sets of valves are shown,more or less sets of valves may be used depending on the number ofnozzles being fed by a particular steam control block. In someembodiments, multiflow steam control blocks 80 a-80 h are each separatedinto multiple steam control blocks, with each subdivided steam controlblock associated with a single nozzle 34.

Multiflow oil control blocks 78 a-78 h and multiflow steam controlblocks 80 a-80 h control the flow of oil and steam, respectively, tonozzles 34. As in the case of the first and second diversion flow blocks60, 95, control blocks 78 a-78 h and 80 a-80 h can be used to preventthe flow of oil and steam to nozzles 34 in the event of needing toreplace one of nozzles 34 or in an emergency. The valves of controlblocks 78 a-78 h and 80 a-80 h are normally open during operation of FCCunit 100 to allow the flow of oil and steam through nozzles 34.

Also included in injector module 12 are a pair of resid oil diversionflow blocks 86 and 94 as shown in FIG. 3. Resid, or residual, oil iswaste oil from other processes or is not fully processed FCC oil whichis recycled to FCC unit 100 and is typically in the form of heavier oilfeeds. These heavier oils can be more difficult to vaporize and atomizebecause of their high boiling points and high viscosity, even at highoperating temperatures. Recycled resid oil can be more responsive to FCCprocessing because it has been previously activated. Each of first andsecond resid oil diversion blocks 86, 94 is similarly configured andeach operates in substantially the same manner. As such, only firstresid oil diversion flow block 86 will be discussed in detail.

First resid oil diversion flow block 86 includes a housing 84 and aresid oil diversion valve 92 coupled to housing 84 as suggested in FIG.3. Housing 84 includes a resid oil inlet 88, with a flange forconnecting oil inlet piping, and a resid oil outlet 90, also with aflange for connecting oil outlet piping. When resid oil diversion valve92 is closed, oil flows from resid oil inlet 88 to resid oil outlet 90and is diverted away from and bypasses standpipe 101. In someembodiments, this bypassed resid oil is sent to a fractionator forfurther processing or to resid oil reservoir as suggested by arrow 99 inFIGS. 1 and 2. When resid oil diversion valve 92 is open, oil flows fromresid oil inlet 88 into body block 46 as further detailed below. Theresid oil diversion valve 92 is controlled hydraulically by DCCM 14 asdescribed in detail below. During normal operation, the first and secondresid oil diversion flow blocks 86, 94 allow oil and steam to flow intobody block 46, and prevent this flow only in emergencies or to conduct anozzle replacement operation as further detailed below.

Flow network 54 is formed in body block 46 for directing the feedstockoil, steam, and resid oil through injector module 12 as suggested inFIG. 6. The various passages, or conduits, are integrally formed withinbody block 46, which is illustratively in the form of a unitary piece ofhigh strength, corrosion-resistant metal. In some embodiments, bodyblock 46 is formed through a casting process to include flow network 54.In some embodiments, body block 46 is machined from a single piece ofmaterial in which the various features, including flow network 54, areshaped by removing portions of the material. In some embodiments, acombination of techniques are used to form body block 46.

Disposed about the outer periphery of body block 46 are a series ofprotrusions extending radially outward from body block 46 as suggestedin FIG. 6. In the illustrative embodiment, these protrusions includeoil/steam inlet protrusions 51, 53 disposed on opposing portions of bodyblock 46 from one another, resid oil inlet protrusions 55, 57 disposedon opposing portions of body block 46 from one another and spaced apartfrom oil/steam inlet protrusions 51, 53, and a plurality of intermediateprotrusions 58, 59 positioned between adjacent inlet protrusions 51, 53,55, 57. Each of oil/steam inlet protrusions 51, 53 is similarlyconfigured and each operates in substantially the same manner. As such,only oil/steam inlet protrusion 51 will be discussed in detail. Each ofresid oil inlet protrusions 55, 57 is similarly configured and eachoperates in substantially the same manner. As such, only resid oil inletprotrusion 55 will be discussed in detail. Each of intermediateprotrusions 58, 59 is similarly configured, and each operates insubstantially the same manner, to their opposing counterparts.

In the illustrative embodiment, oil/steam inlet protrusion 51 includesan upper oil inlet 51 a and a lower steam inlet 51 b as suggested inFIG. 6. Oil inlet 51 a and steam inlet 51 b extend radially inward intoblock body 46. A first oil distribution passage 61 is formed throughintermediate protrusion 58, shown to the right of oil/steam inletprotrusion 51 in FIG. 6, and toward oil/steam inlet protrusion 51 suchthat oil inlet 51 a is in fluid communication with first oildistribution passage 61. In the illustrative embodiment, the process offorming first oil distribution passage 61 also forms an opening 61 d,which can later be closed or used to direct fluid through injectionmodule 12. A second oil distribution passage 62 is formed throughintermediate protrusion 59, shown to the left of oil/steam inletprotrusion 51 in FIG. 6, and toward oil/steam inlet protrusion 51 suchthat oil inlet 51 a is in fluid communication with second oildistribution passage 62. In the illustrative embodiment, the process offorming second oil distribution passage 62 also forms an opening 62 a,which can later be closed or used to direct fluid through injectionmodule 12.

First and second oil distribution passages 61, 62 are arranged todistribute feedstock oil passed through oil inlet 51 a to other areas ofblock body 46 for subsequent distribution to nozzles 34 as suggested inFIG. 6. The number of oil distribution passages can be increased ordecreased depending on the number of nozzles being fed by oil inlet 51a. For example, first and second oil distribution passages 61, 62 arearranged to feed six nozzles. In the illustrative embodiment, a thirdoil distribution passage 63 is formed in body block 46, and in fluidcommunication with first and second oil distribution passages 61, 62, tofeed an additional three nozzles. Third oil distribution passage 63 isformed through intermediate protrusion 58, shown to the right ofoil/steam inlet protrusion 51 in FIG. 6, and toward resid oil inletprotrusion 55. Similar to first and second oil distribution passages 61,62, any opening created through the formation of third oil distributionpassage 63 can later be closed or used to direct fluid through injectionmodule 12. Oil distribution passages 61, 62, 63 together define an oilfeed plenum 64. A similar set of oil distribution passages defininganother oil feed plenum is associated with oil/steam inlet protrusion53.

Similar to oil distribution passages 61, 62, 63, steam distributionpassages 65, 66, 67, 68 are formed in body block 46 to distribute steamreceived through steam inlet 51 b through injection module 12 assuggested in FIG. 6. A first steam distribution passage 65 is formedthrough intermediate protrusion 58, shown to the right of oil/steaminlet protrusion 51 in FIG. 6, and toward oil/steam inlet protrusion 51such that steam inlet 51 b is in fluid communication with first steamdistribution passage 65. In the illustrative embodiment, the process offorming first steam distribution passage 65 also forms an opening 65 d,which can later be closed or used to direct fluid through injectionmodule 12. A second steam distribution passage 66 is formed throughintermediate protrusion 58, shown to the right of oil/steam inletprotrusion 51 in FIG. 6, and toward resid oil inlet protrusion 55 suchthat second steam distribution passage 66 is in fluid communication withfirst steam distribution passage 65. Third and fourth steam distributionpassages 67, 68 are similarly formed through intermediate protrusion 59between oil/steam inlet protrusion 51 and resid oil inlet protrusion 57.Any opening created through the formation of steam distribution passages66, 67, 68 can later be closed or used to direct fluid through injectionmodule 12.

Steam distribution passages 65, 66, 67, 68 are in fluid communicationwith one another to define a steam feed plenum 69 as suggested in FIG.6. Steam feed plenum 69 is in fluid communication with steam inlet 51 bto distribute steam passed through steam inlet 51 b to other areas ofblock body 46 for subsequent distribution to nozzles 34 as furtherdetailed below. A similar set of steam distribution passages defininganother steam feed plenum is associated with oil/steam inlet protrusion53. In some embodiments, the steam feed plenums are in fluidcommunication with one another.

In the illustrative embodiment, resid oil inlet protrusion 55 includes aresid oil inlet 55 a as suggested in FIG. 6. Resid oil inlet 55 aextends radially inward into block body 46. A resid oil distributionpassage 71 is formed through resid oil inlet protrusion 55 and towardintermediate protrusion 59, shown to the right of resid oil inletprotrusion 55 in FIG. 6, such that resid oil inlet 55 a is in fluidcommunication with resid oil distribution passage 71. In theillustrative embodiment, the process of forming resid oil distributionpassage 71 also forms an opening 71 a, which can later be closed or usedto direct fluid through injection module 12. Resid oil distributionpassage 71 is arranged to distribute resid oil passed through resid oilinlet 55 a to other areas of block body 46 for subsequent distributionto nozzles 34. The number of resid oil distribution passages can beincreased or decreased depending on the number of nozzles being fed byresid oil inlet 55 a. For example, resid oil distribution passage 71 isarranged to feed three nozzles. A similar resid oil distribution passageis associated with resid oil inlet protrusion 57.

A plurality of mixing chambers are formed radially inward into bodyblock 46 between each of protrusions 51, 53, 55, 57, 58, 59 asillustrated by mixing chambers 72 a, 72 b, 72 c in FIG. 6. In theillustrative embodiment, each mixing chamber formed in body block 46 issubstantially identical, and any discussion of mixing chambers 72 a, 72b, 72 c applies to the remaining mixing chambers. Each mixing chamber 72a, 72 b, 72 c is arranged to receive a feed of steam and feestock oil,or resid oil as the case may be, to form the working fluid which isdirected through a nozzle-inlet tube 74 a, 74 b, 74 c associated withmixing chambers 72 a, 72 b, 72 c, respectively, toward nozzles 34. Thereis an individual mixing chamber associated with each nozzle 34 such thatthe flow of working fluid can be shut off for one nozzle 34 withoutaffecting the flow to adjacent nozzles 34. For example, shut-off valvereceivers 79 a, 79 b, 79 c are formed through an upper portion of bodyblock 46 to intersect nozzle-inlet tubes 74 a, 74 b, 74 c, respectively,and arranged to receive shut-off valves 98 a, 98 b, 98 c for blocking orallowing the working fluid flowing through mixing chambers 72 a, 72 b,72 c to flow toward nozzles 34 as suggested in FIGS. 1, 4, and 5.

Each steam distribution passage 65, 66, 67, 68 has associated steamoutlets formed radially into body block 46 as illustrated by steamoutlets 65 a, 65 b, 65 c of steam distribution passage 66 in FIG. 6. Inthe illustrative embodiment, each steam outlet formed in body block 46is substantially identical, and any discussion of steam outlets 65 a, 65b, 65 c applies to the remaining steam outlets. Steam flowing throughsteam outlets 65 a, 65 b, 65 c is directed into one of the multiflowsteam control blocks 80 a-80 h, such as multiflow steam control block 80a shown in FIGS. 4 and 5, which controls the flow of steam and directsthe flow of steam toward mixing chambers 72 a, 72 b, 72 c as discussedfurther below.

Each oil distribution passage 61, 62, 63 has associated oil outletsformed through an upper portion into body block 46 as illustrated by oiloutlets 61 a, 61 b, 61 c of third oil distribution passage 63 in FIG. 6.In the illustrative embodiment, each oil outlet formed in body block 46is substantially identical, and any discussion of oil outlets 61 a, 61b, 61 c applies to the remaining oil outlets. Similarly, resid oildistribution passage 71 has associated resid oil outlets which aresubstantially identical to oil outlets 61 a, 61 b, 61 c. Feedstock oil,or resid oil as the case may be, flowing through oil outlets 61 a, 61 b,61 c is directed into one of the multiflow oil control blocks 78 a-78 h,such as multiflow oil control block 78 a shown in FIGS. 4 and 5, whichcontrols the flow of oil and directs the flow of oil towardmixing-chamber inputs 76 a, 76 b, 76 c associated with mixing chambers72 a, 72 b, 72 c, respectively, as discussed further below.

Discussion of how oil and steam flow through injector module 12 will nowbe made with respect to multiflow control blocks 78 b and 80 b, andparticularly with respect to flow through a nozzle 34 c, as illustratedin FIG. 5 and suggested in FIGS. 4 and 6. This discussion should applywith equal force to the remaining multiflow control blocks 78 b-78 h and80 b-80 hand the remaining nozzles 34. The fluid inputs flow inwardlytoward central tube 52 to be released into standpipe 101.

Feedstock oil enters diversion flow block 60 through oil inlet 27 and isdirected toward body block 46 as suggested in FIG. 5. The feedstock oilenters through upper oil inlet 51 a and fills first distribution passage61. The feedstock oil travels upward through oil outlet 61 a toward oilcontrol block 78 b. Dual block and bleed valves 75 c and 82 c are opento allow the feedstock oil to flow through oil control block 78 b whilethrottling valve 77 c controls the rate of flow. In some embodiments,throttling valve 77 c provides an additional shut-off to the flow ofoil. The feedstock oil passes into mixing-chamber input 76 c towardmixing chamber 72 c. As feedstock oil enters mixing chamber 72 c, itstrikes an atomizer plug 91 c which assists in atomizing the feedstockoil for mixing with the steam.

Substantially simultaneously, steam enters diversion flow block 60through steam inlet 93 and is directed toward body block 46 as suggestedin FIG. 5. The steam enters through lower steam inlet 51 b and fillssteam distribution passage 65. The steam travels radially outwardthrough steam outlet 65 a toward steam control block 80 b. Dual blockand bleed valves 85 c and 81 c are open to allow the steam to flowthrough steam control block 80 b while throttling valve 83 c controlsthe rate of flow. In some embodiments, throttling valve 83 c provides anadditional shut-off to the flow of steam. The steam then passes intomixing chamber 72 c. As the steam enters mixing chamber 72 c, it furtheratomizes and mixes with the feedstock oil to form the working fluid andforce the working fluid toward nozzle-inlet tube 74 c.

The mixed feedstock oil and steam travels from mixing chamber 72 ctoward shut-off valve receiver 79 c through nozzle-inlet tube 74 c assuggested in FIG. 5. Nozzle 34 c, similar to the other nozzles 34, isreceived in a nozzle seat 89 c and held in body block 46 by a nozzle cap45 c. The working fluid passes through shut-off valve receiver 79 c intonozzle 34 c and is injected into central tube 52 to react with thecatalyst traveling through standpipe 101. The fluid flow described aboveis substantially similar when resid oil is used.

It can be advantageous to replace a damaged or clogged nozzle 34 whileFCC unit 100 is still in operation to minimize the operational downtimeand maximize efficiency. For example, in the illustrative embodiment, anozzle-removal tool 96 is attached to nozzle 34 c as shown in FIG. 5.Dual block and bleed valves 75 c, 82 c are closed, as further detailedbelow, to block the flow of oil to nozzle 34 c. Nozzle 34 c can then beretracted into nozzle-removal tool 96 to pass out of nozzle seat 89 c.In some embodiments, steam still flows toward nozzle seat 89 c toinhibit the influx of catalyst and reactive material flowing throughcentral tube 52 into flow network 54. Shut-off valve 98 c is then closedto physically block such an influx. Dual block and bleed valves 75 c, 82c are then closed to block the flow of steam and dissipate residualpressure. Nozzle-removal tool 96 can then be removed and fitted with areplacement nozzle 34 c for re-insertion into nozzle seat 89 c using areverse process of that described above. In some embodiments, shut-offvalve 98 c is configured to engage with nozzle 34 c to block the flow ofoil and steam therethrough.

Referring to FIG. 7, there is shown a longitudinal sectional view of oneof nozzles 34. Nozzle 34 includes a distal portion 204 a and a proximalportion 204 b. The distal and proximal portions 204 a, 204 b of nozzle34 are connected together, but are separated by means of a cylindricalslot 206 extending through the nozzle 34. Distal portion 204 a of nozzle34 includes an elongated inner slot 203 extending between an inlet 207and an outlet 202 thereof and through which the oil and steam mixture isdirected into the standpipe 101. Inlet 207 is in fluid communicationwith cylindrical slot 206. A tip 201 of nozzle 34 is angled. Proximalportion 204 b is formed to include a threaded end 208 which also has aset of internal threads 209. In some embodiments, threaded end 208engages with a nozzle cap to hold nozzle 34 in place in injector module12.

Another embodiment of a nozzle 334 for use in injector module 12 isshown in FIG. 7A. Nozzle 334 includes a distal portion 304 a and aproximal portion 304 b. The distal and proximal portions 304 a, 304 b ofnozzle 334 are connected together, but are separated by means of acylindrical slot 306 extending through the nozzle 334. Distal portion304 a of nozzle 334 includes an elongated inner slot 303 extendingbetween an inlet 307 and an outlet 302 thereof and through which the oiland steam mixture is directed into the standpipe 101. Inlet 307 is influid communication with cylindrical slot 306. A tip 301 of nozzle 34 issubstantially hemispherical. Proximal portion 304 b is formed to includea threaded end 308 which also has a set of internal threads 309. In someembodiments, threaded end 308 engages with a nozzle cap to hold nozzle334 in place in injector module 12.

Referring to FIG. 8, there is shown a longitudinal sectional view ofnozzle-removal tool 96 for use in removing and replacing nozzles 34 or334. Nozzle-removal tool 96 includes an elongated cylindrical tube 200having an inner end flange 210 and an outer end cap 212 disposed inabutting contact with inner end flange 210. Disposed on a second,opposed end of elongated cylindrical tube 200 from inner end flange 210is an enlarged cylindrical housing 214. In the illustrative embodimentenlarged cylindrical housing 214 and inner end flange 210 are formedintegrally with elongated cylindrical tube 200. An inner portion 214 aof enlarged cylindrical housing 214 is arranged to surround and engagewith the nozzle cap of the nozzle being replaced. In some embodiments,inner portion 214 a is formed to include threads for coupling to thenozzle caps.

Nozzle-removal tool 96 further includes a hexagonal flange 216 having ableeder port 216 a for displacing the contents of cylindrical tube 200as the nozzle is being retracted as suggested in FIG. 8. Hexagonalflange 216 is fixedly attached to cylindrical tube 200 and allows forrotational displacement of nozzle-removal tool 96 and the nozzle cap towhich it is connected to facilitate nozzle removal and replacement.Disposed within elongated cylindrical tube 200 is an inner shaft 218having threads 220 disposed on its outer surface and extendingsubstantially the length thereof. Inner shaft 218 is securely connectedto elongated cylindrical tube 200 by the engagement of outer threads 220with inner threads 224 on inner portions of end flange 210 and end cap212. Rotation of inner shaft 218 allows it to be further inserted withinelongated cylindrical tube 200 or to be withdrawn from cylindrical tube200.

Inner shaft 218 includes a coupler having an inner threaded portion 228and an outer threaded portion 226 for engaging the end 208 of nozzles 34as suggested in FIG. 8. Inner threaded portion 228 is rotatable relativeto outer threaded portion by engaging an exposed end 222. A seal block230 is coupled to inner shaft 218 to move therewith and block fluid frompassing through nozzle-removal tool 96. In some embodiments,nozzle-removal tool 96 is formed from a high strength, corrosionresistant metal.

Referring to FIG. 9, there is shown a perspective view of dual block andbleed valve 82 c used in controlling the flow of oil through injectormodule 12. All of the dual block and bleed valves are substantiallysimilar in construction, and only a detailed discussion of dual blockand bleed valve 82 c will be made. Valve 82 c includes a cylindricalhollow housing 242, an inner stem 272, and an outer stem 268 as shown inFIGS. 10 and 11. A mounting flange 248 is formed on housing 242 and hasapertures 248 a adapted to receive fasteners (not shown) for mountingvalve 82 c to a supporting structure.

Dual block and bleed valve 82 c includes a number of ports 246, 276, 278for passing fluid through valve 82 c as suggested in FIGS. 10 and 11.The ports 246, 276, 278 can be arranged to act as an input or an outletdepending on the surrounding structure to which valve 82 c is fitted.For example, in the illustrative embodiment, port 278 may be coveredsuch that port 246 acts as an inlet as suggested by arrow 280. Fluidthen flows through dual block bleed valve 82 c and passes out of port276, acting as an outlet, as suggested by arrows 284 a, 284 b. Port 278may also act as an inlet as suggested by arrow 282. In some embodiments,the flow is reversed and fluid passes into valve 82 c through port 276and out of one or both of ports 246, 278. In some embodiments, valve 82c acts as a mixing chamber where oil enters through port 278 while steamenters through port 246, and the mixed fluid exits through port 276.

Outer and inner stems 268, 272 are positioned within housing 242 andarranged to move relative thereto between a fully closed position, shownin FIG. 10, and a fully open position, as shown in FIG. 11. In someembodiments, stems 268, 272 pass through an open end 242 b of housing242 and slide into a bore 242 c until a shoulder 270 of a plug end 270of outer stem 268 engages with a shoulder 242 a of housing 242.

An outer retainer collar 250 surrounds stems 268, 272 and engages withhousing 242 through a threaded connection 265 as suggested in FIGS. 10and 11. Collar 250 engages with graphite packing seals, or glandpacking, 260 to seal against housing 242 and outer stem 268. A threadedconnection 264 allows outer stem 268 to move relative to outer collar250 and housing 242. In some embodiments, a handle 254 is coupled tostem 268 after stems 268, 272 are inserted and collar 250 is coupled tohousing 242.

An inner retainer collar 252 surrounds inner stem 272 and engages withouter stem 268 through a threaded connection 261 as suggested in FIGS.10 and 11. Collar 252 engages with graphite packing seals, or glandpacking, 262 to seal against outer stem 268 and inner stem 272. Athreaded connection 266 with an insert 288 coupled to housing 242 allowsinner stem 272 to move relative to outer stem 268 and housing 242. Insome embodiments, a handle 256 is coupled to stem 272 after stems 268,272 are inserted and collar 252 is coupled to housing 242.

Stems 268, 272 are movable relative to each other as detailed above andas suggested in FIGS. 10 and 11. Plug end 270 of outer stem 268 movestoward or away from a seat 242 d depending on the rotation of handle254. A tapered portion 270 b engages with seat 242 d to block a flow offluid from passing seat 242 d when in the closed position shown in FIG.10. The flow of fluid is instead directed to a bleeder port 258.Similarly, a plug end 274 of inner stem 272 moves toward or away fromseat 242 d depending on the rotation of handle 256. A tapered portion274 a engages with seat 242 d to block a flow of fluid from passing seat242 d when in the closed position shown in FIG. 10. The flow of fluid isinstead directed to a bleeder port 258.

As such, the various flows through valve 82 c can be blocked and bled inmultiple directions and orientations. For example, in the illustrativeembodiment of FIG. 5, valve 82 c is positioned in oil control block 78 bsuch that port 278 is blocked while port 246 acts as an inlet and port276 acts as an outlet. During normal operation, valve 82 c is in theopen position with both plug ends 270, 274 unseated.

Moving plug end 270 to a closed position will block the flow of oilcoming from first oil distribution passage 61 and through oil controlblock 78 b and port 246 from flowing out of port 276. A back pressurewithin mixing chamber 72 c would be allowed to bleed out through bleederport 258 until plug end 274 is moved to the closed position. Theopposite would also be true if plug end 274 were seated first, whereback pressure in mixing chamber 72 c would be blocked and the flow ofoil could bleed. In some embodiments, a pressure gauge can be attachedto bleeder port 258 to detect residual pressures during operation ofvalve 82 c. The disclosed block and bleed valve 82 c thus provides asimple, single device for the detection and release of excess residualpressure, thereby enhancing reliability and safety.

Basic Description of Operation

One embodiment of a flow diagram and flow control arrangement will nowbe described in relation to FIGS. 12A-12D, which when laid out such thatthe lettered lines are aligned shows a complete diagram. The assemblydetailed above can be arranged to handle more than two feedstocksupplies, but for this description, we will use two feedstock oils—afeedstock oil and a resid oil. These two oils are separately supplied tothe injector module at a pressure between about 50 psig and 300 psig,and are preheated to approximately 500° F. Steam is also supplied to theinjector module at pressures between about 50 psig and 350 psig and attemperatures between saturated steam for the pressures and about 550° F.which has some superheat in the steam. As a result, the injector moduleis operating at a temperature of approximately 450 to 500° F. over itssurfaces and throughout the supplied material. Steam is suppliedtypically at two different points on the injector module to reducepiping connected to the injector module. Condensate can occur in theinjector module when the unit is not operating or even during certainreduced operation, so systems can be included for controlling steamcondensate.

Feedstock Oil Control and Injection

The injector module controls the flow of feedstock and resid oils in thefollowing manner as directed by DCCM 14. Hydraulic oil is supplied atpressure to the injector module to control the position of thecontrolling and safety valves which operate the injector module.Specifically, hydraulic solenoid valve SOLI is a normally closedsolenoid valve that when de-energized removes the piloting pressure offof two logic valves PCV11 and PCV12. This solenoid valve, whenenergized, provides piloting hydraulic fluid pressure to the activatingport on the logic valves PCV11 and PCV12, thus causing the valves toopen. These logic valves are therefore a digital valve—meaning they areeither open or closed, and are simple and reliable two position, twoport valves. The solenoid valve SOLI is a three port, two positionvalve. The failsafe nature of how this circuit is arranged provides thesupply feedstock oil to the injector module a path into the rest of thecircuit when SOLI is energized, but if there is a power failure or anemergency function or a fire, power is removed from SOLI and thefeedstock oil is diverted to another selected direction and locationthat is safe. This same circuit is duplicated with SOL1A and PCV11A andPCV12A for redundancy of control functions. This duplication is providedas most applications require absolute reliability, so a redundant systemdoes assure this functionality. If redundancy is not desired by the enduser, the second circuit is easily not installed as each of thesecircuits is built into a function block assembly which can be bolted onor removed simply by unbolting and using a cover plate for thatparticular location.

PCV11 or PCV11A is located in the feedstock gas oil line. The PCV12 orPCV12A valves provide a flowpath to a diversion point usually a locationwhere the oil can be recycled eventually back to the process, but is notprovided to the standpipe assembly for safety. This function is providedto maintain safe operation in the case of emergency conditions. Thisfeed diversion module 294 can be arranged also to be in series insteadof in parallel function for additional safety if the end user sodesires.

As the feedstock oil passes the feed diversion module 294, it entersinto a first control module 296 which is an assembly for controllingvalves and isolation valves. The control module 296 includes a servocontrol modulating valve SSV1A which is able to be isolated with doubleblock valves MV101A, MV102A, MV103A and MV104A on the upstream anddownstream positions. These isolation valves MV101A, MV102A, MV103A, andMV104A maintain the current state of and provide proper isolation withthe bleed valves to atmosphere MV105A, MV106A, MV107A, MV108A valves.These latter valves are designated for each individual injection pointwith letters A, B, C, etc. for each of the above valves. The SSV1A valvecan be electrically operated as a servo solenoid or proportional typevalve or is supplied as a hydraulically controlled servo modulatingcontrol valve. Within the block valves described above and associatedwith the servo control modulating valve SSV1A are the followingcomponents:

-   -   flow meter transmitter FT101A;    -   pressure transmitter PT101A; and    -   pressure gauge PG101A.

The above components are located downstream of servo control modulatingvalve SSV1A and upstream of flow transmitter FT101A. A pressuretransmitter PT102A and a pressure gauge PG102A are located downstream offlow transmitter FT101A. The above items can all be isolated at the sametime as the servo solenoid valve SSV1A with the manual valves MV101A,MV102A, MV103A, and MV104A. This provides maintenance capability forchanging any of the components in this group during operation.Therefore, servo control modulating valve SSV1A, pressure transmitterPT101A, pressure gauge PG101A, flow meter transmitter FT101A, pressuretransmitter PT102A, and pressure gauge PG102A can all be individuallyremoved and replaced during operation of the DCCM safely and in aprovable safe manner.

The purpose of first control module 296 is to control the feedstockfluid flow to the feed injection nozzle for that particular controlcircuit. Flow is measured for each individual injection nozzle circuit,with pressures upstream and downstream of the flow transmitter providedso a data comparison can be made between the upstream and downstreampressures of the flow transmitter FT101A, which comparisons can becorrelated to flow at different pressures supplied and at different flowrates. Further, control valve SSV1A can be used to adjust the flow offeedstock so that adjustment of the entire number of nozzles can be madewhile online to provide optimum flow for different feedstock materialsand pressures, temperatures, and types.

From the first control module 296, the feedstock oil flows to injectorassembly FNM101A. This can be an injection nozzle, such as nozzle 34 or334, that the end user wants to use. The user may select other nozzlesas well which fit the injector module. In this configuration, the feedinjection nozzle module FNM101A mixes and breaks down the feedstock oilwith steam or other product. The injection module is designed to beremoved and replaced as a bolt-on assembly and permits easy designchanges to the nozzle assembly.

The feedstock injection nozzle module FNM101A is isolated on theupstream side by the double block and bleed valves MV103A and MV104A,MV107A, MV108A and is isolated and bled on the downstream side of thefeed injection nozzle module FNM101A by block valves MV109A and MV110Aand bleed valves MV111A and MV112A. Feedstock injection nozzle moduleFNM101A can, therefore, be isolated during operation of the DCCM andremoved and replaced, if necessary. This is a unique feature of theassembly.

The feedstock oil is broken down inside the injection nozzle moduleFNM101A with steam and the mixed materials are carried to the catalystin the riser section, or equivalent section in other processes, throughthe injector module to an inserted nozzle. Through this pathway insidethe injector module to the inserted nozzle, the same profile of thepassageway as required by the individual assemblies in different systemsis maintained. The nozzle insert protrudes through the piping wall andin some cases refractory or other liner materials. In some embodiments,this nozzle insert is made from solid stellite to provide resistance towear from the severe erosion that can take place in these types ofsystems. The nozzle insert can also be removed from the piping and linerassembly during operation of the injector module in a safe manner. Ahydraulic extractor designed especially for this function is used tomaintain a nozzle insert if it wears. The nozzle inserts can be pulledback through a packing by the hydraulic extractor and then the processfunction of the catalyst can be isolated using blocking valves MV109Aand MV110A. A determination that these valves are holding properly canbe made via bleed valves MV111A and MV112A as they are open toatmosphere to verify that the MV109A and MV110A valves are holdingproperly when isolated. Steam purge through these valves when closing ismaintained to prevent catalyst from entering into the valve assembliesMV109A, MV110A, MV111A, or MV112A.

Resid Oil Control and Injection

The injector module controls the resid oil in the following manner.Hydraulic oil is supplied under pressure to injector module to controlthe position of the controlling and safety valves which operate theinjector module. Specifically, hydraulic solenoid valve SOL2 is anormally closed solenoid valve that when de-energized removes thepiloting pressure off of two logic valves PCV15 and PCV16. This solenoidvalve SOL2 when energized provides piloting hydraulic fluid underpressure to the activating ports of logic valves PCV15 and PCV16, thuscausing the valves to open. These logic valves are therefore a digitalvalve—meaning they are either open or closed, and are simple andreliable two position two port valves. The solenoid valve SOL2 is athree port, two position valve. The failsafe nature of how this circuitarrangement provides the supply resid oil to the injector module is apath to the rest of the circuit when SOL2 is energized, but if there isa power failure or an emergency function or a fire, power is removedfrom SOL2 and the resid oil is diverted to another selected directionand location that is safe. This same circuit is duplicated with SOL2Aand PCV15A and PCV16A for redundancy of this control function. Thisduplication is provided as most applications require absolutereliability, so a redundant system assures this functionality that isgenerally required. If redundancy is not desired by the end user, thesecond circuit is easily not installed as each of these circuits isbuilt into a function block assembly which can be bolted on or removedsimply by unbolting and using a cover plate for that particularlocation.

PCV15 or PCV15A is located in the resid gas oil line and blocks the flowof fluid to the injector module. PCV16 or PCV16A valves provide aflowpath to a diversion point which is typically a location where theoil can be recycled eventually back to the process, but is not providedto the riser assembly for safety. This function is provided to maintainsafe operation in the case of emergency conditions. The feed diversionmodule 298 can be arranged also to be in series instead of in parallelfunction for additional safety if the end user so desires.

As the resid oil passes the feed diversion module 298, it enters into asecond control module 300 which is an assembly where controlling valvesand isolation valves are located. This assembly consists of a servocontrol modulating valve SSV2A which is able to be isolated with doubleblock valves MV121A, MV122A, MV123A and MV124A on the upstream anddownstream positions. These isolation valves MV121A, MV122A, MV123A, andMV124A maintain the state of and provide proper isolation withatmospheric bleed valves MV125A, MV126A, MV127A, MV128A valves. Theselatter valves are designated for each individual injection point withletters A, B, C etc. for each of the above valves. The SSV1A valve canbe electrically operated as a servo solenoid or proportional type valveor is supplied as a hydraulically controlled servo modulating controlvalve. Within the block valves described above and associated with theservo control modulating valve SSV2A are the following components:

-   -   flow meter transmitter FT121A;    -   pressure transmitter PT121A; and    -   pressure gauge PG121A.

The above components are located downstream of SSV2A and upstream offlow transmitter FT121A. The following two components are locateddownstream of flow transmitter FT121A:

-   -   pressure transmitter PT122A; and    -   pressure gauge PG122A.

The above items can all be isolated at the same time by means of servosolenoid valve SSV2A, with manual valves MV121A, MV122A, MV123A, andMV124A. This provides a maintenance capability for changing any of thecomponents in this group during operation. Therefore, the SSV2A, PT121A,PG121A, FT121A, PT122A, PG122A can all be individually removed andreplaced during operation of the DCCM safely and in a provable safemanner.

The purpose of the second control module 300 is to control the residfluid flow to the feed injection nozzle for that particular controlcircuit. Flow is measured for each individual injection nozzle circuit,and pressures upstream by pressure transmitter PT121A, pressure gaugePG121A and downstream by PT122A, PG122A of flow transmitter FT121A areprovided so data comparison can be made between the upstream anddownstream pressures of flow transmitter FT121A and can be correlated toflow at different pressures supplied and at different flowrates.Further, control valve SSV2A can be used to adjust the flow of resid sothat adjustment of the entire number of nozzles can be made while onlineto find the optimum flow for different resid materials and pressures,temperatures, and types.

From the second control module 300, resid oil flows to resid injectionnozzle module FNM121A. This can be an injection nozzle, such as nozzle34 or 334, that the end user wants to use. The user may select othernozzles as well which fit the injector module. In this configuration,feed injection nozzle module FNM121A mixes and breaks down the resid oilwith steam or other product. This module is designed to be removed andreplaced as a bolt-on assembly and permits easy design changes to thenozzle assembly.

Resid injection nozzle module FNM121A is isolated on the upstream sideby the double block valves MV123A and MV124A, and bleed valves MV127A,MV128A and is isolated and bled on the downstream side of the feedinjection nozzle module FNM121A by block valves MV129A and MV130A andbleed valves MV131A and MV132A. The feed injection nozzle module FNM121Acan, therefore, be isolated during operation of the injector module andremoved and replaced, if necessary. This is a unique feature of theassembly.

The resid oil is broken down inside the feed injection nozzle moduleFNM121A with steam and the mixture is carried to the catalyst in theriser section, or equivalent section in other processes, through theinjector module to an inserted nozzle. Through this complete pathwayinside the injector module to the inserted nozzle assembly, the sameprofile of the passageway as required by the individual arrangementsfrom different sources is maintained. The nozzle insert protrudesthrough the piping wall and in some cases through refractory or otherliner materials. In some embodiments, this nozzle insert is made fromsolid stellite to provide resistance to wear from the severe erosionthat can take place in these types of environments. The inserted nozzleis also able to be removed from the piping and liner assembly duringoperation of the injector module in a safe manner. A hydraulic pullerdesigned specifically for this function can be used for maintenance onthe nozzle inserts if they wear. The nozzle inserts can be pulled backthrough a packing with the hydraulic extractor and then the processfunction of the catalyst can be isolated with MV109A and MV110A anddetection that these valves are holding properly can be made with MV111Aand MV112A as they are open to the atmosphere and can be used to provethat the MV109A and MV110A valves are holding when isolated. Steam purgethrough these valves when closing is maintained to prevent catalyst fromentering into valve assemblies MV109A, MV110A, MV111A, or MV112A.

Steam Control System Dispersion Steam Control to the Injection Nozzles

In one illustrative embodiment, injector module controls dispersionsteam in the following manner. Hydraulic oil is supplied under pressureto the injector module to control the position of the controlling andsafety valves which operate the injector module unit. Specifically,hydraulic solenoid valve SOL3 is a normally closed solenoid valve thatwhen de-energized removes the piloting pressure from logic valve PCV22.Solenoid valve SOL3 when de-energized provides piloting hydraulic fluidpressure to the activating port on logic valve PCV22, thus causing thevalve to open. The logic valve is therefore a digital valve—meaning itis either open or closed, and is a simple and reliable two position twoport valve. The solenoid valve SOL3 is a three port, two position valve.The failsafe nature of this circuit provides the dispersion steam supplycontinuously to the injector module and to the rest of the circuit whenSOL3 is de-energized. SOL3 must be de-energize if the flow of steam tothe system is to be stopped.

This same circuit is duplicated in SOL3A and PCV22A for redundancy ofthe control function. This duplication is provided as most applicationsrequire absolute reliability, so a redundant system assures thisfunctionality that is generally required. If redundancy is not desiredby the end user, the second circuit is not installed easily as each ofthese circuits is built into a function block assembly which can bebolted on or removed simply by unbolting and using a cover plate forthat particular location.

PCV22A is located in the dispersion steam line and either blocks theflow of steam to the injector module control modules or permits the flowto occur during normal and emergency conditions. This function isprovided to maintain safe operation in the case of emergency conditions,also so that steam is always supplied to the injector module. Condensatewill occur if the SOL3A solenoid valve is energized during operation, socondensate control valves should be provided by the user.

As dispersion steam passes the isolation valves PCV22 or PCV22A, itenters into a third control module 302 which is an assembly wherecontrolling valves and isolation valves are located. This assemblyconsists of a servo control modulating valve SSV3A which is able to beisolated by means of double block valves MV141A, MV142A, MV143A andMV144A on the upstream and downstream positions. These isolation valvesMV141A, MV142A, MV143A, and MV144A maintain the state of and provideproper isolation with atmospheric bleed valves MV145A, MV146A, MV147A,MV148A. These valves are designated for each individual injection pointwith letters A, B, C etc. for each of the above valves. The SSV3A valvecan be electrically operated as a servo solenoid or proportional typevalve or is supplied as a hydraulically controlled servo modulatingcontrol valve. Within the block valves described above and associatedwith the servo control modulating valve SSV3A are the followingcomponents:

-   -   flow meter transmitter FT141A;    -   pressure transmitter PT141A; and    -   pressure gauge PG141A.

The above components are located downstream of SSV3A and upstream offlow transmitter FT141A. The following two components are locateddownstream of flow transmitter FT141A:

-   -   pressure transmitter PT142A; and    -   pressure gauge PG142A.

The above items can all be isolated at the same time by means of servosolenoid valve SSV3A, with manual valves MV141A, MV142A, MV143A, andMV144A. This provides a maintenance capability for changing any of thecomponents in this group during operation. Therefore, the SSV3A, PT141A,PG141A, FT141A, PT142A, PG142A can all be individually removed andreplaced during operation of the DCCM safely and in a provable safemanner.

The purpose of a third control module 302 is to control the dispersionsteam flow to feed injection nozzles FNM101A or FNM121A for eachparticular control circuit of the feedstock gas or resid oils. Flow ofdispersion steam is measured for each individual injection nozzlecircuit, pressures upstream by pressure transmitter PT141A, pressuregauge PG141A and downstream by PT142A, PG142A of flow transmitter FT141Aare provided so data comparison can be made between the upstream anddownstream pressures of flow transmitter FT121A and is correlated toflow at different pressures supplied and at different flowrates.Further, control valve SSV3A can be used to adjust the flow ofdispersion steam so that adjustment of the entire number of nozzles canbe made while online to find the optimum flow for different feedstockmaterials and pressures, temperatures, and types.

Feedstock injection nozzle module FNM101A or FNM121A is isolated on thedispersion steam upstream side by double block valves MV149A and MV150Aand bleed valves are provided as MV151A, MV152A.

Feed injection nozzle module FNM101A or FNM121A can, therefore, be fullyisolated during operation of the DCCM and removed and replaced ifnecessary. This is a unique feature of the assembly.

Emergency Steam to the Injection Nozzles

In one embodiment, the injector module controls the emergency steam inthe following manner. Hydraulic oil is supplied under pressure to theinjector module to control the position of the controlling and safetyvalves which operate the injector module unit. Specifically, hydraulicsolenoid valve SOL4 is a normally closed solenoid valve that whende-energized removes the piloting pressure off of logic valve PCV26.This solenoid valve SOL4 when de-energized provides piloting hydraulicfluid pressure to the activating port on the logic valve PCV26, thuscausing the valve to open. The logic valve is therefore a digitalvalve—meaning it is either open or closed, and is a simple and reliabletwo position two port valve. The solenoid valve SOL4 is a three port,two position valve. The failsafe nature of this circuit providesdispersion steam continuously to injector module as well as to the restof the system when SOL4 is energized. SOL4 must be de-energize to stopthe flow of steam to the system.

This same circuit is duplicated with SOL4A and PCV26A for redundancy ofcontrol function. This duplication is provided as most applicationsrequire absolute reliability, so a redundant system assures thisfunctionality that is generally required. If redundancy is not desiredby the end user, the second circuit is not installed easily as each ofthese circuits is built into a function block assembly which can bebolted on or removed simply by unbolting and using a cover plate forthat particular location.

PCV26A is located in the emergency steam line and blocks the flow ofsteam to injector module injection nozzle module FNM101A or FNM121Adirectly to the connection point of each dispersion steam going to eachnozzle. This function is provided to lift the catalyst up the riser in atypical process during an emergency situation where feedstock oil orresid are diverted away from the injector module. This maintains safeoperation under emergency conditions and keeps the catalyst from beingslumped in the riser which is a critically bad situation if it occurs.Condensate will occur if the SOL4 solenoid valves are energized duringoperation, so condensate control valves should be supplied by the user.

As emergency steam passes isolation logic valve PCV26 or PCV26A, it hasa control section module which consists of a flow transmitter FT161A anddouble block (isolation) valves MV161A, MV162A, MV163A, MV164A in theupstream and downstream positions of the flow transmitter. Theseisolation valves MV161A, MV162A, MV163A, and MV164A are able to hold andprovide proper isolation via bleed valves MV165A, MV166A, MV167A, MV168Avalves to atmosphere. These valves are designated for each individualinjection point with letters A, B, C, etc. for each of the above valves.The following components are located downstream of the split for eachnozzle:

-   -   flow meter transmitter FT161A;    -   pressure transmitter PT161A; and    -   pressure gauge PG161A.

The above items can all be isolated with manual valves MV161A, MV162A,MV163A, and MV164A. This combination provides maintenance capability forchanging any of the components in this group during operation.Therefore, PT161A, PG161A, FT161A can all be individually removed andreplaced during operation of the DCCM safely and in a provable safemanner.

The purpose of a fourth control module 304 is to control the emergencysteam flow to the feed injection nozzles FNM101A or FNM121A for eachparticular control circuit of the feedstock gas or resid oils. Flow ofemergency steam is measured for each individual injection nozzlecircuit, pressures upstream by PT161A, PG161A of flow transmitter FT161Aprovide data comparison to assure the proper amount of emergency steamis getting to each nozzle and to the riser assembly.

Feedstock injection nozzle module FNM101A or FNM121A is isolated fromemergency steam lines by the same valves that isolate the dispersionsteam. These valves include block valves MV149A and MV150A, with bleedvalves also provided as valves MV151A, MV152A.

Additional instrumentation provided on an as needed basis includes soundsensors on all, or at least some, of the nozzle insert assemblies. Thesesensors indicate the condition of the nozzles. These sensors may not beneeded due to the unique design of the nozzle inserts as wear or erosionare not believed to be an issue. If sound is an issue, then the soundsensors can be used to indicate the condition of a nozzle.

Further, temperature indicators for the risers located in severallocations on the liner of the injector module can be incorporated on acustom basis to indicate the health of the refractory. This indicationwould prevent any erosion that might occur from forming a hole throughthe main body of the DCCM.

Temperature transmitters TT181 and TT182 are provided on the main headerof the injector module ports for the gas oil main feedstock port and forthe resid feedstock port. These temperatures are used along with densityindicators provided by an end user to determine in part the flowrate andthe mixing percentages to be used in the output maximizing program forthe DCCM to execute.

Controller Assembly

A controller, such as DCCM 14, is provided to monitor, record andcontrol the following components and points within the FCC system:

In some embodiments, control functions of DCCM include:

-   -   1. All servo control valves for feedstock gas oil;    -   2. All servo control valves for resid feedstock oil;    -   3. All solenoid valves for feedstock gas oil; and    -   4. All solenoid valves for resid feedstock oil.

In some embodiments, data is collected from:

-   -   1. Feedstock gas oil temperature TT181;    -   2. Feedstock resid oil temperature TT182;    -   3. Steam supply temperature TT183;    -   4. Pressure transmitters for feedstock gas oil PT101A, PT102A;    -   5. Pressure transmitters for feedstock resid oil PT121A, PT122A;    -   6. Pressure transmitters for dispersion steam PT141A, PT142A;    -   7. Pressure transmitters for emergency steam PT161A;    -   8. Flow transmitters for feedstock gas oil FT101A;    -   9. Flow transmitters for feedstock resid oil FT121A;    -   10. Flow transmitters for dispersion steam FT141A;    -   11. Flow transmitters for emergency steam FT161A; and    -   12. Sound sensors for individual nozzles as needed.

In some embodiments, a minimum of 12 nozzles is used. In someembodiments, 18 to 24 nozzles are used. In some embodiments, up to 30nozzles are used. In some embodiments, more than 30 nozzles are used.The number of nozzles may be increased or decreased depending on thesize of the standpipe being fed by the nozzles. The DCCM will take thedata for the setpoint flowrate from the refinery or chemical or otherindustrial process and will adjust the flow rate through each nozzlesystem to provide a combined total flowrate to meet the setpoint.Additional data combined with temperatures, mass density and otherfactors from other sections of the system that would affect yield aremonitored for total output conversion into usable product. This meansthat input from outside would be minimally:

-   -   1. Riser temperature data points;    -   2. Total catalyst circulation rate;    -   3. Total carbon make on catalyst;    -   4. Total yield recovered in the vapor recovery unit;    -   5. Total liquid product make;    -   6. Oxygen content at the flue gas stack;    -   7. Opacity input for the catalyst going out the stack;    -   8. Catalyst activity; and    -   9. Catalysts fines make.

With these data points, adjustment to dispersion steam is made tomaximize liquid yield and to reduce overall carbon make on the catalyst.This data can be used to understand the performance of each nozzle. Thisdata can further be used to determine the extent of deterioration of thecatalyst and, therefore, the amount of catalyst fines reduction thatcould help opacity on the stack meters, and the total emissions of CO2and CO to the atmosphere.

Another embodiment of an injector module 412 in accordance with thepresent disclosure for use in FCC unit 100 is shown in FIGS. 13 and 14.Injector module 412 includes a plurality of nozzles 434 coupled to amanifold 432. Manifold 432 includes a central tube 452, a flow network454, and a flow control assembly 448. A steam input tube 460, feedstockoil input tube 462, and resid oil input tube 486 are coupled to flownetwork 454 to supply manifold 432 with feedstock oil, resid oil, andsteam. The feedstock oil, resid oil, and steam flow through manifold tonozzles 434. The flow of feedstock oil, resid oil, and steam iscontrolled by flow control assembly 448 as directed by DCCM 14. Nozzles434 are arranged to extend through openings 449 formed through an innersurface of central tube 452, and refractory liner 447, such that nozzles434 can direct fluid into central tube 452.

Flow control assembly 448 includes a plurality of flow controllers 470a-470 l coupled to flow network 454 and circumferentially spaced fromone another as suggested in FIGS. 13 and 14. Each flow controller 470a-470 l includes a steam control block 480 a-480 l, respectively, and anoil control block 478 a-478 l, respectively. In the illustrativeembodiment, oil control blocks 478 a, 478 c, 478 i are configured tocontrol a flow of resid oil through manifold 32 towards nozzles 34 whilethe remaining oil control blocks are configured to control a flow offeedstock oil as further detailed below. As such, three nozzles arearranged to direct resid oil into central tube 452 while the remainingnozzles are arranged to direct feedstock oil into central tube 452. Anycombination of oil control blocks is possible, including more or lessoil control blocks for controlling a flow of resid oil through manifold32.

Flow network 454 includes a plurality of annular feed plenums 463, 464,465 arranged to surround central tube 452 to direct fluid aroundmanifold 432 for distribution to flow controllers 470 a-470 l andnozzles 434 as suggested in FIG. 15. Steam input tube 460 is coupled toa steam feed plenum 463 and configured to direct steam through an inletopening 460 a into steam feed plenum 463 to fill steam feed plenum 463with steam. Feedstock oil input tube 462 is coupled to an oil feedplenum 464 and configured to direct feedstock oil through an inletopening 462 a into oil feed plenum 464 to fill oil feed plenum 464 withfeedstock oil. Resid oil input tube 486 is coupled to a resid oil feedplenum 465 and configured to direct resid oil through an inlet opening486 a into resid oil feed plenum 465 to fill resid oil feed plenum 465with resid oil. In some embodiments, resid oil feed plenum 465 isremoved when no flow controllers 470 a-470 l are configured forcontrolling a flow of resid oil to nozzles 434.

In the illustrative embodiment, central tube 452 includes a pipe section490 and a pair of flanges 488, 492 coupled to opposing ends of pipesection 490 as suggested in FIG. 15. In some embodiments, feed plenums463, 464, 465 are formed prior to attachment of flanges 488, 492 andslid over pipe section 490 into position. In some embodiments, feedplenums 463, 464, 465 are formed from straight sections of tubing whichare bent around pipe section 290 and have their ends welded together. Anadapter ring 482 is also coupled to central tube 452 and is configuredto couple nozzle-feed blocks 479 a-479 l with central tube 452, thoughonly nozzle-feed blocks 479 c and 479 h are visible in FIG. 15. In theillustrative embodiment, adapter ring 482 is cast or machined as aunitary component and slid over pipe section 490 into position.

Adapter ring 482 is formed to include a nozzle seat 489 g for receivingnozzle 434 g as suggested in FIG. 16. Nozzle 434 g extends throughnozzle-feed block 479 g, adapter ring 482, and opening 449 g. A cap 445g couples nozzle 434 g with nozzle-feed block 479 g and covers an openend of nozzle 434 g.

Discussion will now be made regarding the flow of feedstock oil andsteam through injector module 412 as illustrated for a nozzle 434 g andassociated flow controller 470 g in FIGS. 16 and 17. The belowdescription is applicable to any other flow controller 470 a-470 l usedto direct feedstock oil and steam to one of nozzles 434. In theillustrative embodiment, steam travelling through steam feed plenum 463passes through a steam supply port 463 g and into steam control block480 g of flow controller 470 g as suggested in FIG. 16. A platform 421 gis positioned between steam feed plenum 463 and steam control block 480g to provide a flat surface for coupling steam control block 480 g withsteam feed plenum 463. The flow of steam passes through a dual block andbleed valve 485 g and toward an intermediate throttling valve 483 g. Theflow of steam passes through throttling valve 483 g and travels toward amixing chamber 472 g.

Feedstock oil travelling through oil feed plenum 464 passes through anoil supply port 464 g and into steam control block 480 g of flowcontroller 470 g as suggested in FIG. 16. A platform 422 g is positionedbetween oil feed plenum 464 and steam control block 480 g to provide aflat surface for coupling steam control block 480 g with oil feed plenum464. The flow of oil passes through a transfer conduit 476 g out ofsteam control block 480 g and into oil control block 478 g as suggestedin FIGS. 16 and 17. The flow of oil passes through a dual block andbleed valve 475 g and an intermediate throttling valve 477 g toward atransfer conduit 487 g as suggested in FIG. 17. The flow of oil travelsthrough transfer conduit 487 g and into mixing chamber 472 g to mix withthe flow of steam as suggested in FIGS. 16 and 17.

The mixed steam and feedstock oil passes out of mixing chamber 472 g andinto a shut-off valve 498 g as suggested in FIG. 16. The flow of mixedsteam and feedstock oil travels through shut-off valve 498 g and into anozzle-inlet tube 474 g formed in nozzle-feed block 479 g. The flow ofmixed steam and feedstock oil travels through nozzle 434 g and out ofnozzle-injection ports 439 g formed in nozzle 434 g. Various plugs andcaps, such as plugs 423 g, 424 g and cap 445 g, are used to sealopenings formed during formation of the various conduits through flowcontroller 470 g.

Adapter ring 482 is formed to include a nozzle seat 489 i for receivingnozzle 434 i as suggested in FIG. 18. Nozzle 434 i extends throughnozzle-feed block 479 i, adapter ring 482, and opening 449 i. A cap 445i couples nozzle 434 i with nozzle-feed block 479 i and covers an openend of nozzle 434 i.

Discussion will now be made regarding the flow of resid oil and steamthrough injector module 412 as illustrated for a nozzle 434 i andassociated flow controller 470 i in FIGS. 18 and 19. The belowdescription is applicable to any other flow controller 470 a-470 l usedto direct resid oil and steam to one of nozzles 434. In the illustrativeembodiment, steam travelling through steam feed plenum 463 passesthrough a steam supply port 463 i and into steam control block 480 i offlow controller 470 i as suggested in FIG. 18. A platform 421 i ispositioned between steam feed plenum 463 and steam control block 480 ito provide a flat surface for coupling steam control block 480 i withsteam feed plenum 463. The flow of steam passes through a dual block andbleed valve 485 i and toward an intermediate throttling valve 483 i. Theflow of steam passes through throttling valve 483 i and travels toward amixing chamber 472 i.

Resid oil travelling through resid oil feed plenum 465 passes through aresid oil supply port 465 i and into steam control block 480 i of flowcontroller 470 i as suggested in FIG. 18. A platform 425 i is positionedbetween resid oil feed plenum 465 and steam control block 480 i toprovide a flat surface for coupling steam control block 480 i with residoil feed plenum 465. The flow of resid oil passes through a transferconduit 476 i out of steam control block 480 i and into oil controlblock 478 i as suggested in FIGS. 18 and 19. The flow of resid oilpasses through a dual block and bleed valve 475 i and an intermediatethrottling valve 477 i toward a transfer conduit 487 i as suggested inFIG. 17. The flow of resid oil travels through transfer conduit 487 iand into mixing chamber 472 i to mix with the flow of steam as suggestedin FIGS. 18 and 19.

The mixed steam and resid oil passes out of mixing chamber 472 i andinto a shut-off valve 498 i as suggested in FIG. 18. The flow of mixedsteam and resid oil travels through shut-off valve 498 i and into anozzle-inlet tube 474 i formed in nozzle-feed block 479 i. The flow ofmixed steam and resid oil travels through nozzle 434 i and out ofnozzle-injection ports 439 i formed in nozzle 434 i. Various plugs andcaps, such as plugs 423 i, 424 i, 426 i and cap 445 i, are used to sealopenings formed during formation of the various conduits through flowcontroller 470 i.

In illustrative embodiments, a cracking unit includes a cracking feed,such as gas oil from a vacuum distillation tower which is brought intocontact with a hot cracking catalyst at the base of a tall, columnarriser wherein the cracking takes place. The cracking feed travels up theriser to its top concurrently with the catalyst with the crackingproduct separated from the catalyst in a disengaging vessel, commonlyreferred to as a “reactor.” The reactor includes cyclone separators forseparating the catalyst from the cracking products which are then passedto a product recovery section of the unit for separation into variouscracked fractions. The separated catalyst is passed to a regenerator, inwhich the coke laid down by the cracking process is oxidatively removed,thus restoring the catalyst to its active state for providing heat forthe endothermic cracking process by the combustion of the coke. Theregenerated catalyst is returned to a lower portion of the crackingriser for contact with the cracking feed.

In illustrative embodiments, the nature of the cracking feed injectionzone in the catalytic cracking reactor is critical to the overallcracking process. To optimize the cracking process, it is necessary tocontact the feed as uniformly as possible with the catalyst so as toprocure the catalyst/oil ratio which is most favorable to the desiredproduct yield and distribution. In addition, essentially completeatomization of any unvaporized feed must be effected as fast and asclose to the injection zone as possible. In practice, these requirementshave given rise to a considerable number of technical problems arisingnot only from the basic difficulties of achieving uniform contactbetween a finely-divided solid (the catalyst) and a liquid (the crackingfeed), but also because cracking units are generally required to handlevery large quantities of both catalyst and cracking feed. In order toimprove the efficiency of the catalytic cracking process, it isdesirable to have the feed molecules reach the active catalyst particlesto the maximum extent possible and in the shortest possible time frame.

During operation of a typical FCC Unit and process, no nozzle can bereplaced. This is a significant limitation because the yield of the FCCis directly related to nozzle integrity, and the cost to replace anozzle can be very high. Presently, a single valve controls the flow offeed into the riser as well as the bypass flow back to the fractionatorof the catalyst. This valve operates very slowly and is prone tofailure. The valves and actuators involved with the introduction ofemergency steam for lifting the catalyst in the riser are also slow inoperation and sometimes fail to provide the emergency steam in a timelymanner.

In illustrative embodiments, the injector module can be used in otherprocesses where fluid mixing of two or more products occurs.

In illustrative embodiments, the injector module of the presentdisclosure increases a yield in feed conversion in an FCC system by theuse of multiple nozzles and nozzles of reduced size for greater controlover oil feedstock distribution and input, resulting in the need forless combustion air in the process. The need for less combustion air isdue to less carbon being deposited on the catalyst which must be burnedoff by the combustion air. The increased efficiency and the reducedcarbon deposited on the catalyst with less air consumption results inless pollutants being discharged to the atmosphere. This represents asubstantial benefit to the refiner seeking to meet federal and staterequirements on emissions from the refinery. In other words, the refinercan use the same amount of air and discharge to the atmosphere the sameamount of emissions per its federal and state licenses, but can increasethe throughput of the FCC Unit, or other process, resulting in greaterefficiency and profitability.

In illustrative embodiments, the nozzle insert, when located in theinjector module and extending through the refractory liner, permits wearof the tip surface without any degradation in the nozzle shape. Theshape of the port of the nozzle can affect dispersion of the feed oilinto the process. The disclosed nozzle insert maintains the same portpattern throughout its operating lifetime, and provides the sameinjection pattern all the way through and will not erode and assume adifferent shape.

In illustrative embodiments, the internal network of piping formed inthe block simplifies and reduces the feedstock piping and other externalpiping which is typically required to feed each nozzle. A unitarymonitoring and control module for controlling an injector module in anFCC process can easily be incorporated by retrofitting in existing FCCreactors.

In illustrative embodiments, multiple temperature indications of theliner outside surface of the injector module, such as in four to sixlocations, is monitored by the DCCM to monitor the health and conditionof the refractory. This is to assure the refractory condition issatisfactory for continued operation. Further, the injector module iscontrolled in such a way as to provide much greater control of eachfunction taking place at individual injection points rather thanproviding overall control of the entire system on a macro basis.Therefore, the DCCM feed injection system provides an increasedthroughput with greater efficiency due to the greater number and moreprecise control over the system monitoring and control locations.

In illustrative embodiments, a feedstock injector module for use incontinuous cyclical processes employing fluidized solid techniques,e.g., a hydrocarbon fluid catalytic cracking (FCC) process, is providedin the form of a solid block of high strength, heat resistant materialwhich includes a plurality of nozzles integrally formed in the injectormodule for spraying feedstocks via integrally formed passageways andnozzles into the riser vessel, or reactor. This arrangement permits theuse of increased numbers of smaller nozzles for improved atomization andgreater flexibility in feedstock spray patterns providing increasedoutput yield. The module is disposed about the riser and extends intothe feedstock flow profile in the reactor. The injector module is easilyreplaced as a single unit in the reactor, and includes multiplefeedstock passageways to accommodate various feedstocks such as gas oil,medium light cycle oil, and resid oil, as well as steam, forsimultaneous injection into the reactor.

In illustrative embodiments, separate nozzles are provided within theinterior of the standpipe for the feed oil and the resid oil. The numberof nozzles depends upon the diameter of the standpipe. Emergency steamis introduced into the standpipe separate and apart from theintroduction of the steam used in atomizing the oil feedstock.

In illustrative embodiments, in a refinery process of a fluidizedcatalyst cracking unit (FCCU), nozzles stick into a vertical pipe thatinject oil onto catalyst. These nozzles have a tip on the end of themthat spray the oil in much of the same way as a high pressure sidewalkwasher or building washer would work as a spray nozzle that leavesgenerally a flat spray and the spray pattern is made in such a way toform as much coverage of the inside of that pipe with multiple nozzlesaround the outside of the pipe as is possible.

In illustrative embodiments, the equipment sprays oil on a catalyst. Thecatalyst is about the size of small sand particles. Oil is spayed in thecatalyst and oil temperature is around 450-500 degrees. The catalystitself is at 1300 degrees Fahrenheit when the oil contacts it, and itvaporizes the oil almost immediately and that vapor is station goingfrom liquid to vapor phase increases the volume dramatically and itlifts the catalyst up vertically. The reacting mixture enters anothervessel where the catalyst is actually separated from the vapor andreused in the process.

There has previously been a particular limit in how many nozzles can beput into a certain diameter of pipe. One reason for this is that thenozzles themselves are large and fill significant portions of the pipeand adding more would cause them to contact one another. As such, theproblem is how to get more nozzles into the pipe. So for example, aboutfour nozzles would previously fit in a small pipe diameter of 24 inches.Using the injector module of the present disclosure, 12 nozzles will fitin a pipe diameter of 24 inches. Previously, in a 30 inch diameter pipe,5 to 6 nozzles would fit. Using the injector module of the presentdisclosure, 16 nozzles will fit in a pipe diameter of 30 inches. Usingthe injector module of the present disclosure, 18-20 nozzles will fit ina pipe diameter of 40 inches. Using the injector module of the presentdisclosure, 32 nozzles will fit in a pipe diameter of 60 inches.

In illustrative embodiments, instead of a 6 inch nozzle, or a 4 inchnozzle, a 1½ or 2 inch nozzle is used. As such, previously there wasdispersion coverage of about 65% to 80%. Using the injector module ofthe present disclosure, dispersion coverage of about 94% to 95% can berealized, and up to 99% depending on the size of pipe and number ofnozzles used.

Another problem is making an assembly where a nozzle can be pulled outwhile the unit is in service. In other words, remove it from servicethat actually replace the nozzle in case something goes wrong with it.

In illustrative embodiments, you can tune the FCC unit to either makemore gasoline or more kerosene depending on how you arrange thepressures and the textures that you are operating at. It is estimatedthat using the injector module of the present disclosure, a 2% gain ofyield is experience over other processes. The cracking process separatesthe oil into gases to convert them into gasoline, kerosene, naphtha,butane and down to the light cycle oils or heavy cycle oils.

In illustrative embodiments, the disclosed design is able to control theflow rate of oil through each nozzle. The system includes a set pointfor feed for the total amount of feed going to the riser to permitdistribution of oil to all of those nozzles in the system. Oil feed isautomatically controlled through a control valve and instrumentationassociated with the control valve. The feed oil of the present system iscontrolled with the control valve and a PLC program that controls thevalve to an overall set point that includes a flow meter for each feednozzle. They system also includes a pressure transmitter on each feednozzle upstream and downstream of the overall control. With this system,the operator knows how much flow is going through each nozzle and thepressure at which each of the nozzles are operating. From a diagnosticstand point, the operator knows whether each nozzle is working or not orwhether it is plugged up or whether it is eroded or whether it is notworking right. In some embodiments, tips of the nozzles are made of astelite material which is heat and abrasion resistant.

In illustrative embodiments, each nozzle includes feed oil and steam.There are two different steam flows coming into the nozzle, dispersesteam and an overall control steam. The system includes control valves,flow transmitters, and pressure transmitters to control the steam. If asteam pressure header loses pressure an alarm sounds and the operatorcan reduce system pressures until the problem can be resolved. The steamcontrol allows the operator to change the amount and rate of steam fordifferent feed stocks coming into the unit. Current systems only haveaggregate control of steam, meaning one steam control valve thatoperates to all of the feed nozzles and one aggregate control valve onthe feed side for all of those nozzles. The present disclosure includeindividualized steam to each feed nozzle and an operator is to controleach feed nozzle individually with both steam and with feed and mix themaccordingly, automatically to a certain riser temperature, to a certainflow rate. These factors are controlled by the plc program and thedistributor control system.

In illustrative embodiments, the system includes one manifold ring forfeed, one manifold ring for steam and the steam is divided up betweenthe two flows of steam within the block. The system also includes athird ring that is used for a different feed stock, such as recycledoil. Recycled oil is usually a heavier stock oil. Before recycled oilgoes into most refineries, it is put into the riser of the FCC unit toseparate out gasoline from the heavy residual. The present systemincludes the third ring so that residual oil can be mixed with the feedoil. The third manifold ring includes an individual steam ring so thatresidual oil can be adjusted. The present disclosure allows an operatorto mix the residual oil and the feed oil and send the blended oil intothe nozzles. The system allows an operator to set a particular nozzle tobe fed just by the residual oil or they can create a mixture of bothresidual oil and gas oil.

In illustrative embodiments, since the present system is one block thereare a minimized number of connections coming through the block. Thefirst connection is for feed oil, which, in the example is delivered bya 6, 8 or 10 inch pipe, depending on the size of the unit. The secondconnection to the block is for steam. The third connection to the blockis for residual oil. The fourth connection is for condensate that isremoved from the steam manifold ring.

In illustrative embodiments, block sections are bolted together using atortuous pathway of mating surfaces to eliminate leaking. In someembodiments, a carbon based or metal foil gasket is placed betweenmating blocks to form seals. This arrangement eliminates the potentialflange leaks that take place at each one of the flange points in atypical pipe system. The block utilize cartridge valves. The cartridgevalve is a valve that is positioned down into the block of steel. Thecartridge valve can seal up different ports and the valve can have twoports coming through the valve, three ports coming through the valve orfour.

While particular embodiments of the present disclosure have beendescribed, it will be obvious skilled in the relevant arts that changesand modifications may be made without departing from the disclosure inits broader aspects. Therefore, the aim in the appended claims is tocover all such changes and modifications that fall within the truespirit and scope of the disclosure. The matters set forth in theforegoing description and accompanying drawings is offered by way ofillustration only and not as a limitation. The actual scope of thedisclosure is intended to be defined in the following claims when viewedin their proper perspective based on the prior art.

1-21. (canceled)
 22. A fluid injection system for a fluid catalyticcracking unit having a cracking standpipe into which oil, steam, and acatalyst are introduced at elevated pressure and temperature to crackthe oil into constituent portions, the fluid injection systemcomprising: a manifold coupled to the cracking standpipe, the manifoldhaving plurality of inner passages for distributing flows of oil andsteam through the manifold, a plurality of inlets in fluid communicationwith the plurality of inner passages, and a plurality of outletsseparated from the plurality of inlets and in fluid communication withthe plurality of inner passages; a plurality of separate mixing chamberscircumferentially disposed about the manifold, each mixing chamberconfigured to atomize oil supplied to the mixing chamber and mix theatomized oil with steam supplied to the mixing chamber; a plurality ofmultiflow control blocks circumferentially disposed about the manifoldand coupled to the plurality of outlets, each multiflow control blockconfigured for controlling the flows of oil and steam into acorresponding one of the plurality of mixing chambers; and a pluralityof nozzles circumferentially disposed about the standpipe and extendingthrough respective apertures into the standpipe, the plurality ofnozzles in fluid communication with the plurality of mixing chambers fordirecting the oil and steam mixture into the standpipe in a controlledmanner for reaction with the catalyst.
 23. The fluid injection system ofclaim 22, wherein each of the multiflow control blocks includes aplurality of valves for controlling the flows of oil and steam into thecorresponding mixing chamber.
 24. The fluid injection system of claim23, wherein each of the valves is a dual block and bleed valve.
 25. Thefluid injection system of claim 24, wherein each of the dual block andbleed valves includes first and second independently movable members foreither blocking or allowing the flow of oil or steam through the valve.(New) The fluid injection system of claim 24, wherein each of the dualblock and bleed valves comprises: a housing having an axial bore and anannular seat, the housing formed to include a first port formed throughthe housing and positioned on a first side of the annular seat and asecond port formed through the housing and positioned on a second sideof the annular seat opposite the first side, a first stem having anannular body and a first plug end coupled to a first end of the annularbody, a second end of the annular body received in the bore of thehousing such that the first plug end is positioned on the first side ofthe annular seat, the first stem configured to move axially relative tothe housing between an open position where the first plug end is spacedapart from the annular seat and a closed position where the first plugend is engaged with and seated against the annular seat to seal anopening through the annular seat, and a second stem having a shaft and asecond plug end coupled to a first end of the shaft, a second end of theshaft received in the annular body of the first stem such that thesecond plug end is positioned on the second side of the annular seat,the second stem configured to move axially relative to the housingbetween an open position where the second plug end is spaced apart fromthe annular seat and a closed position where the second plug end isengaged with and seated against the annular seat to seal the openingthrough the annular seat, wherein the annular seat is formed to includea bleeder port extending through the housing and configured to providemeans for passing a fluid received in the housing through one of thefirst or second ports out of the housing until at least one of the firstand second plug ends is seated against the annular seat.
 27. The fluidinjection system of claim 22, wherein each multiflow control blockincludes an oil control block and a steam control block coupled to acorresponding one of the plurality of mixing chamber.
 28. The fluidinjection system of claim 27, wherein the control blocks are disposedsubstantially symmetrically on the manifold about the standpipe.
 29. Thefluid injection system of claim 22, further including a plurality ofshutoff valves, each shutoff valve configured to block fluidcommunication between corresponding ones of the plurality of mixingchambers and plurality of nozzles at the selection of a user.
 30. Thefluid injection system of claim 29, further including a plurality ofthreaded couplings attaching a respective nozzle to an inner portion ofthe manifold in a removable manner.
 31. The fluid injection system ofclaim 30, further including a removal tool coupled to one of the nozzlesand engaging the manifold for removing the nozzle from the manifold in asealed manner during operation of the fluid catalytically cracking unitand preventing unwanted escape of oil and steam from the standpipe. 32.The fluid injection system of claim 31, wherein the removal tool isadapted for replacing the first nozzle with a second nozzle whilepreventing escape of oil and steam from the standpipe.
 33. The fluidinjection system of claim 22, wherein the flow of oil is provided to acorresponding inner passage of the plurality of inner passages at apressure between about 50 and 300 psig and at a temperature of about500° F., and the flow of steam is provided to a corresponding innerpassage of the plurality of inner passages at a pressure between about50 and 350 psig and at a temperature of about 550° F.
 34. A nozzle foruse in a fluid catalytic cracking unit for directing oil and steam atelevated pressure and temperature into a standpipe for forminghydrocarbon products, the nozzle comprising: an elongated member havingfirst and second opposed ends and an inner slot extending along at leasta portion of the length of the elongated member; a connectingarrangement disposed on the first end of the elongated member formounting the nozzle in the fluid catalytic cracking unit; a firstopening disposed on the second end of the elongated member, wherein thefirst opening forms a discharge end of the inner slot; and a secondopening disposed on the elongated member for receiving and directing oiland steam into the inner slot, wherein the second opening is adapted toreceive a shutoff valve for terminating the flow of oil and steam to theinner slot of the elongated member.
 35. A fluid injection system for usewith a standpipe of a fluid catalytic cracking unit, the fluid injectionsystem comprising: a data collection and control module, an injectormodule having a plurality of nozzles positioned within the standpipe anda manifold positioned around the standpipe and configured to directfluid inputs provided to the injector module toward the nozzles, themanifold formed to include a flow network therein configured to permitthe passage of oil and steam through the manifold, a plurality ofcontrol blocks coupled to the manifold and configured to control a flowof fluid toward the nozzles through the flow network of the manifold,and wherein the data collection and control module is configured topermit monitoring of flows of oil and steam through the control blocksand for operating the control blocks such that fluid flow through thenozzles is controlled.
 36. The fluid injection system of claim 35,wherein the flow network is also configured to permit a flow of residualoil through the manifold.